Your search keyword '"Panzeri, Stefano"' showing total 20 results

1. Evolutionarily conserved fMRI network dynamics in the mouse, macaque, and human brain.

Author

Gutierrez-Barragan D, Ramirez JSB, Panzeri S, Xu T, and Gozzi A

Subjects

Animals, Male, Humans, Mice, Biological Evolution, Adult, Macaca, Species Specificity, Macaca mulatta, Brain Mapping methods, Phylogeny, Magnetic Resonance Imaging methods, Brain physiology, Brain diagnostic imaging, Connectome methods, Nerve Net physiology, Nerve Net diagnostic imaging

Abstract

Evolutionarily relevant networks have been previously described in several mammalian species using time-averaged analyses of fMRI time-series. However, fMRI network activity is highly dynamic and continually evolves over timescales of seconds. Whether the dynamic organization of resting-state fMRI network activity is conserved across mammalian species remains unclear. Using frame-wise clustering of fMRI time-series, we find that intrinsic fMRI network dynamics in awake male macaques and humans is characterized by recurrent transitions between a set of 4 dominant, neuroanatomically homologous fMRI coactivation modes (C-modes), three of which are also plausibly represented in the male rodent brain. Importantly, in all species C-modes exhibit species-invariant dynamic features, including preferred occurrence at specific phases of fMRI global signal fluctuations, and a state transition structure compatible with infraslow coupled oscillator dynamics. Moreover, dominant C-mode occurrence reconstitutes the static organization of the fMRI connectome in all species, and is predictive of ranking of corresponding fMRI connectivity gradients. These results reveal a set of species-invariant principles underlying the dynamic organization of fMRI networks in mammalian species, and offer novel opportunities to relate fMRI network findings across the phylogenetic tree., (© 2024. The Author(s).)

Published

2024

2. Increased fMRI connectivity upon chemogenetic inhibition of the mouse prefrontal cortex.

Author

Rocchi F, Canella C, Noei S, Gutierrez-Barragan D, Coletta L, Galbusera A, Stuefer A, Vassanelli S, Pasqualetti M, Iurilli G, Panzeri S, and Gozzi A

Subjects

Animals, Mice, Neural Pathways physiology, Prefrontal Cortex diagnostic imaging, Brain, Magnetic Resonance Imaging methods

Abstract

While shaped and constrained by axonal connections, fMRI-based functional connectivity reorganizes in response to varying interareal input or pathological perturbations. However, the causal contribution of regional brain activity to whole-brain fMRI network organization remains unclear. Here we combine neural manipulations, resting-state fMRI and in vivo electrophysiology to probe how inactivation of a cortical node causally affects brain-wide fMRI coupling in the mouse. We find that chronic inhibition of the medial prefrontal cortex (PFC) via overexpression of a potassium channel increases fMRI connectivity between the inhibited area and its direct thalamo-cortical targets. Acute chemogenetic inhibition of the PFC produces analogous patterns of fMRI overconnectivity. Using in vivo electrophysiology, we find that chemogenetic inhibition of the PFC enhances low frequency (0.1-4 Hz) oscillatory power via suppression of neural firing not phase-locked to slow rhythms, resulting in increased slow and δ band coherence between areas that exhibit fMRI overconnectivity. These results provide causal evidence that cortical inactivation can counterintuitively increase fMRI connectivity via enhanced, less-localized slow oscillatory processes., (© 2022. The Author(s).)

Published

2022

3. Neuroscience: Turbulent times for brain information processing.

Author

Bondanelli G and Panzeri S

Subjects

Cognition, Brain, Neurosciences

Abstract

A recent study shows that rare long-range connections between brain areas may considerably improve transmission of information between areas. The study suggests that information may propagate better through long-range connections when neural activity exhibits turbulent dynamics., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

4. Stimulus-dependent relationships between behavioral choice and sensory neural responses.

Author

Chicharro D, Panzeri S, and Haefner RM

Subjects

Action Potentials, Animals, Feedback, Psychological, Macaca, Models, Animal, Models, Neurological, Photic Stimulation, Signal Detection, Psychological, Visual Pathways physiology, Visual Perception, Behavior, Animal, Brain physiology, Choice Behavior, Sensory Receptor Cells physiology

Abstract

Understanding perceptual decision-making requires linking sensory neural responses to behavioral choices. In two-choice tasks, activity-choice covariations are commonly quantified with a single measure of choice probability (CP), without characterizing their changes across stimulus levels. We provide theoretical conditions for stimulus dependencies of activity-choice covariations. Assuming a general decision-threshold model, which comprises both feedforward and feedback processing and allows for a stimulus-modulated neural population covariance, we analytically predict a very general and previously unreported stimulus dependence of CPs. We develop new tools, including refined analyses of CPs and generalized linear models with stimulus-choice interactions, which accurately assess the stimulus- or choice-driven signals of each neuron, characterizing stimulus-dependent patterns of choice-related signals. With these tools, we analyze CPs of macaque MT neurons during a motion discrimination task. Our analysis provides preliminary empirical evidence for the promise of studying stimulus dependencies of choice-related signals, encouraging further assessment in wider data sets., Competing Interests: DC, SP, RH No competing interests declared, (© 2021, Chicharro et al.)

Published

2021

5. Computation of the electroencephalogram (EEG) from network models of point neurons.

Author

Martínez-Cañada P, Ness TV, Einevoll GT, Fellin T, and Panzeri S

Subjects

Brain cytology, Electrodes, Humans, Neurons metabolism, alpha-Amino-3-hydroxy-5-methyl-4-isoxazolepropionic Acid metabolism, gamma-Aminobutyric Acid metabolism, Brain physiology, Electroencephalography methods, Models, Neurological, Neurons physiology

Abstract

The electroencephalogram (EEG) is a major tool for non-invasively studying brain function and dysfunction. Comparing experimentally recorded EEGs with neural network models is important to better interpret EEGs in terms of neural mechanisms. Most current neural network models use networks of simple point neurons. They capture important properties of cortical dynamics, and are numerically or analytically tractable. However, point neurons cannot generate an EEG, as EEG generation requires spatially separated transmembrane currents. Here, we explored how to compute an accurate approximation of a rodent's EEG with quantities defined in point-neuron network models. We constructed different approximations (or proxies) of the EEG signal that can be computed from networks of leaky integrate-and-fire (LIF) point neurons, such as firing rates, membrane potentials, and combinations of synaptic currents. We then evaluated how well each proxy reconstructed a ground-truth EEG obtained when the synaptic currents of the LIF model network were fed into a three-dimensional network model of multicompartmental neurons with realistic morphologies. Proxies based on linear combinations of AMPA and GABA currents performed better than proxies based on firing rates or membrane potentials. A new class of proxies, based on an optimized linear combination of time-shifted AMPA and GABA currents, provided the most accurate estimate of the EEG over a wide range of network states. The new linear proxies explained 85-95% of the variance of the ground-truth EEG for a wide range of network configurations including different cell morphologies, distributions of presynaptic inputs, positions of the recording electrode, and spatial extensions of the network. Non-linear EEG proxies using a convolutional neural network (CNN) on synaptic currents increased proxy performance by a further 2-8%. Our proxies can be used to easily calculate a biologically realistic EEG signal directly from point-neuron simulations thus facilitating a quantitative comparison between computational models and experimental EEG recordings., Competing Interests: The authors have declared that no competing interests exist.

Published

2021

6. Mathematical studies of the dynamics of finite-size binary neural networks: A review of recent progress.

Author

Fasoli D and Panzeri S

Subjects

Action Potentials, Algorithms, Animals, Computational Biology, Humans, Models, Statistical, Probability, Brain physiology, Models, Neurological, Nerve Net, Neurons physiology, Neurosciences trends

Abstract

Several mathematical approaches to studying analytically the dynamics of neural networks rely on mean-field approximations, which are rigorously applicable only to networks of infinite size. However, all existing real biological networks have finite size, and many of them, such as microscopic circuits in invertebrates, are composed only of a few tens of neurons. Thus, it is important to be able to extend to small-size networks our ability to study analytically neural dynamics. Analytical solutions of the dynamics of small-size neural networks have remained elusive for many decades, because the powerful methods of statistical analysis, such as the central limit theorem and the law of large numbers, do not apply to small networks. In this article, we critically review recent progress on the study of the dynamics of small networks composed of binary neurons. In particular, we review the mathematical techniques we developed for studying the bifurcations of the network dynamics, the dualism between neural activity and membrane potentials, cross-neuron correlations, and pattern storage in stochastic networks. Then, we compare our results with existing mathematical techniques for studying networks composed of a finite number of neurons. Finally, we highlight key challenges that remain open, future directions for further progress, and possible implications of our results for neuroscience.

Published

2019

7. Infraslow State Fluctuations Govern Spontaneous fMRI Network Dynamics.

Author

Gutierrez-Barragan D, Basson MA, Panzeri S, and Gozzi A

Subjects

Animals, Autistic Disorder genetics, Cluster Analysis, Female, Male, Mice, Mice, Inbred C57BL, Random Allocation, Rest, Spatio-Temporal Analysis, Autistic Disorder physiopathology, Brain physiology, Magnetic Resonance Imaging

Abstract

Spontaneous brain activity as assessed with resting-state fMRI exhibits rich spatiotemporal structure. However, the principles by which brain-wide patterns of spontaneous fMRI activity reconfigure and interact with each other remain unclear. We used a framewise clustering approach to map spatiotemporal dynamics of spontaneous fMRI activity with voxel resolution in the resting mouse brain. We show that brain-wide patterns of fMRI co-activation can be reliably mapped at the group and subject level, defining a restricted set of recurring brain states characterized by rich network structure. Importantly, we document that the identified fMRI states exhibit contrasting patterns of functional activity and coupled infraslow network dynamics, with each network state occurring at specific phases of global fMRI signal fluctuations. Finally, we show that autism-associated genetic alterations entail the engagement of atypical functional states and altered infraslow network dynamics. Our results reveal a novel set of fundamental principles guiding the spatiotemporal organization of resting-state fMRI activity and its disruption in brain disorders., (Copyright © 2019 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2019

8. Cracking the Neural Code for Sensory Perception by Combining Statistics, Intervention, and Behavior.

Author

Panzeri S, Harvey CD, Piasini E, Latham PE, and Fellin T

Subjects

Animals, Choice Behavior, Behavior, Animal physiology, Brain physiology, Optogenetics, Perception physiology, Statistics as Topic

Abstract

The two basic processes underlying perceptual decisions-how neural responses encode stimuli, and how they inform behavioral choices-have mainly been studied separately. Thus, although many spatiotemporal features of neural population activity, or "neural codes," have been shown to carry sensory information, it is often unknown whether the brain uses these features for perception. To address this issue, we propose a new framework centered on redefining the neural code as the neural features that carry sensory information used by the animal to drive appropriate behavior; that is, the features that have an intersection between sensory and choice information. We show how this framework leads to a new statistical analysis of neural activity recorded during behavior that can identify such neural codes, and we discuss how to combine intersection-based analysis of neural recordings with intervention on neural activity to determine definitively whether specific neural activity features are involved in a task., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published

2017

9. Computing the Local Field Potential (LFP) from Integrate-and-Fire Network Models.

Author

Mazzoni A, Lindén H, Cuntz H, Lansner A, Panzeri S, and Einevoll GT

Subjects

Computer Simulation, Electromagnetic Fields, Humans, Membrane Potentials physiology, Synaptic Transmission physiology, Action Potentials physiology, Brain physiology, Brain Mapping methods, Models, Neurological, Nerve Net physiology, Neurons physiology

Abstract

Leaky integrate-and-fire (LIF) network models are commonly used to study how the spiking dynamics of neural networks changes with stimuli, tasks or dynamic network states. However, neurophysiological studies in vivo often rather measure the mass activity of neuronal microcircuits with the local field potential (LFP). Given that LFPs are generated by spatially separated currents across the neuronal membrane, they cannot be computed directly from quantities defined in models of point-like LIF neurons. Here, we explore the best approximation for predicting the LFP based on standard output from point-neuron LIF networks. To search for this best "LFP proxy", we compared LFP predictions from candidate proxies based on LIF network output (e.g, firing rates, membrane potentials, synaptic currents) with "ground-truth" LFP obtained when the LIF network synaptic input currents were injected into an analogous three-dimensional (3D) network model of multi-compartmental neurons with realistic morphology, spatial distributions of somata and synapses. We found that a specific fixed linear combination of the LIF synaptic currents provided an accurate LFP proxy, accounting for most of the variance of the LFP time course observed in the 3D network for all recording locations. This proxy performed well over a broad set of conditions, including substantial variations of the neuronal morphologies. Our results provide a simple formula for estimating the time course of the LFP from LIF network simulations in cases where a single pyramidal population dominates the LFP generation, and thereby facilitate quantitative comparison between computational models and experimental LFP recordings in vivo.

Published

2015

10. Tracing the Flow of Perceptual Features in an Algorithmic Brain Network.

Author

Ince RA, van Rijsbergen NJ, Thut G, Rousselet GA, Gross J, Panzeri S, and Schyns PG

Subjects

Algorithms, Brain Mapping, Humans, Models, Neurological, Brain physiology, Cognition physiology, Nerve Net physiology, Perception physiology

Abstract

The model of the brain as an information processing machine is a profound hypothesis in which neuroscience, psychology and theory of computation are now deeply rooted. Modern neuroscience aims to model the brain as a network of densely interconnected functional nodes. However, to model the dynamic information processing mechanisms of perception and cognition, it is imperative to understand brain networks at an algorithmic level--i.e. as the information flow that network nodes code and communicate. Here, using innovative methods (Directed Feature Information), we reconstructed examples of possible algorithmic brain networks that code and communicate the specific features underlying two distinct perceptions of the same ambiguous picture. In each observer, we identified a network architecture comprising one occipito-temporal hub where the features underlying both perceptual decisions dynamically converge. Our focus on detailed information flow represents an important step towards a new brain algorithmics to model the mechanisms of perception and cognition.

Published

2015

11. Speech rhythms and multiplexed oscillatory sensory coding in the human brain.

Author

Gross J, Hoogenboom N, Thut G, Schyns P, Panzeri S, Belin P, and Garrod S

Subjects

Adult, Auditory Cortex physiology, Female, Functional Laterality physiology, Functional Neuroimaging, Humans, Magnetic Resonance Imaging, Magnetoencephalography, Male, Speech physiology, Young Adult, Brain physiology, Speech Perception physiology

Abstract

Cortical oscillations are likely candidates for segmentation and coding of continuous speech. Here, we monitored continuous speech processing with magnetoencephalography (MEG) to unravel the principles of speech segmentation and coding. We demonstrate that speech entrains the phase of low-frequency (delta, theta) and the amplitude of high-frequency (gamma) oscillations in the auditory cortex. Phase entrainment is stronger in the right and amplitude entrainment is stronger in the left auditory cortex. Furthermore, edges in the speech envelope phase reset auditory cortex oscillations thereby enhancing their entrainment to speech. This mechanism adapts to the changing physical features of the speech envelope and enables efficient, stimulus-specific speech sampling. Finally, we show that within the auditory cortex, coupling between delta, theta, and gamma oscillations increases following speech edges. Importantly, all couplings (i.e., brain-speech and also within the cortex) attenuate for backward-presented speech, suggesting top-down control. We conclude that segmentation and coding of speech relies on a nested hierarchy of entrained cortical oscillations., Competing Interests: The authors have declared that no competing interests exist.

Published

2013

12. Dynamic Brain-Machine Interface: a novel paradigm for bidirectional interaction between brains and dynamical systems.

Author

Szymanski FD, Semprini M, Mussa-Ivaldi FA, Fadiga L, Panzeri S, and Vato A

Subjects

Humans, Brain physiology, Man-Machine Systems

Abstract

Brain-Machine Interfaces (BMIs) are systems which mediate communication between brains and artificial devices. Their long term goal is to restore motor functions, and this ultimately demands the development of a new generation of bidirectional brain-machine interfaces establishing a two-way brain-world communication channel, by both decoding motor commands from neural activity and providing feedback to the brain by electrical stimulation. Taking inspiration from how the spinal cord of vertebrates mediates communication between the brain and the limbs, here we present a model of a bidirectional brain-machine interface that interacts with a dynamical system by generating a control policy in the form of a force field. In our model, bidirectional communication takes place via two elements: (a) a motor interface decoding activities recorded from a motor cortical area, and (b) a sensory interface encoding the state of the controlled device into electrical stimuli delivered to a somatosensory area. We propose a specific mathematical model of the sensory and motor interfaces guiding a point mass moving in a viscous medium, and we demonstrate its performance by testing it on realistically simulated neural responses.

Published

2011

13. Sensory neural codes using multiplexed temporal scales.

Author

Panzeri S, Brunel N, Logothetis NK, and Kayser C

Subjects

Animals, Computer Simulation, Humans, Information Theory, Psychomotor Performance physiology, Reaction Time physiology, Action Potentials physiology, Brain physiology, Perception physiology, Sensation physiology, Sensory Receptor Cells physiology, Time Perception physiology

Abstract

Determining how neuronal activity represents sensory information is central for understanding perception. Recent work shows that neural responses at different timescales can encode different stimulus attributes, resulting in a temporal multiplexing of sensory information. Multiplexing increases the encoding capacity of neural responses, enables disambiguation of stimuli that cannot be discriminated at a single response timescale, and makes sensory representations stable to the presence of variability in the sensory world. Thus, as we discuss here, temporal multiplexing could be a key strategy used by the brain to form an information-rich and stable representation of the environment., (Copyright 2009 Elsevier Ltd. All rights reserved.)

Published

2010

14. A toolbox for the fast information analysis of multiple-site LFP, EEG and spike train recordings.

Author

Magri C, Whittingstall K, Singh V, Logothetis NK, and Panzeri S

Subjects

Algorithms, Animals, Computer Simulation, Electroencephalography, Electronic Data Processing, Electrophysiology, Macaca, Models, Neurological, Signal Processing, Computer-Assisted, Brain physiology, Information Theory, Neurons physiology

Abstract

Background: Information theory is an increasingly popular framework for studying how the brain encodes sensory information. Despite its widespread use for the analysis of spike trains of single neurons and of small neural populations, its application to the analysis of other types of neurophysiological signals (EEGs, LFPs, BOLD) has remained relatively limited so far. This is due to the limited-sampling bias which affects calculation of information, to the complexity of the techniques to eliminate the bias, and to the lack of publicly available fast routines for the information analysis of multi-dimensional responses., Results: Here we introduce a new C- and Matlab-based information theoretic toolbox, specifically developed for neuroscience data. This toolbox implements a novel computationally-optimized algorithm for estimating many of the main information theoretic quantities and bias correction techniques used in neuroscience applications. We illustrate and test the toolbox in several ways. First, we verify that these algorithms provide accurate and unbiased estimates of the information carried by analog brain signals (i.e. LFPs, EEGs, or BOLD) even when using limited amounts of experimental data. This test is important since existing algorithms were so far tested primarily on spike trains. Second, we apply the toolbox to the analysis of EEGs recorded from a subject watching natural movies, and we characterize the electrodes locations, frequencies and signal features carrying the most visual information. Third, we explain how the toolbox can be used to break down the information carried by different features of the neural signal into distinct components reflecting different ways in which correlations between parts of the neural signal contribute to coding. We illustrate this breakdown by analyzing LFPs recorded from primary visual cortex during presentation of naturalistic movies., Conclusion: The new toolbox presented here implements fast and data-robust computations of the most relevant quantities used in information theoretic analysis of neural data. The toolbox can be easily used within Matlab, the environment used by most neuroscience laboratories for the acquisition, preprocessing and plotting of neural data. It can therefore significantly enlarge the domain of application of information theory to neuroscience, and lead to new discoveries about the neural code.

Published

2009

15. Extracting information from neuronal populations: information theory and decoding approaches.

Author

Quian Quiroga R and Panzeri S

Subjects

Algorithms, Animals, Humans, Neural Networks, Computer, Signal Processing, Computer-Assisted, Action Potentials physiology, Brain physiology, Information Theory, Nerve Net physiology, Neurons physiology, Neurophysiology methods

Abstract

To a large extent, progress in neuroscience has been driven by the study of single-cell responses averaged over several repetitions of stimuli or behaviours. However,the brain typically makes decisions based on single events by evaluating the activity of large neuronal populations. Therefore, to further understand how the brain processes information, it is important to shift from a single-neuron, multiple-trial framework to multiple-neuron, single-trial methodologies. Two related approaches--decoding and information theory--can be used to extract single-trial information from the activity of neuronal populations. Such population analysis can give us more information about how neurons encode stimulus features than traditional single-cell studies.

Published

2009

16. Correlations and the Encoding of Information in the Nervous System

Author

Panzeri, Stefano, Schultz, Simon R., Treves, Alessandro, and Rolls, Edmund T.

Published

1999

17. Speech Rhythms and Multiplexed Oscillatory Sensory Coding in the Human Brain

Author

Gross, Joachim, Hoogenboom, Nienke, Thut, Gregor, Schyns, Philippe, Panzeri, Stefano, Belin, Pascal, Garrod, Simon, Institut de biologie et chimie des protéines [Lyon] (IBCP), Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS), Institute for Clinical Neuroscience and Medical Psychology, University of Düsseldorf, Düsseldorf, Germany, Institute for Neuroscience and Psychology, University of Glasgow, Glasgow, United Kingdom, Institut de Neurosciences de la Timone (INT), Aix Marseille Université (AMU)-Centre National de la Recherche Scientifique (CNRS), Institute for Neuroscience and Psychology, University of Glasgow, Glasgow, and ANR-11-IDEX-0001,Amidex,INITIATIVE D'EXCELLENCE AIX MARSEILLE UNIVERSITE(2011)

Subjects

Adult, Male, genetic structures, QH301-705.5, Cognitive Neuroscience, Right hemisphere, [SDV.NEU.NB]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]/Neurobiology, Neuroimaging, Functional Laterality, Young Adult, otorhinolaryngologic diseases, Humans, Speech, Speech signal processing, Biology (General), Biology, Natural Language Processing, Computational Neuroscience, Quantitative Biology::Neurons and Cognition, Functional Neuroimaging, Auditory cortex, Computational Biology, Brain, Magnetoencephalography, Phonemes, [SDV.NEU.SC]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]/Cognitive Sciences, Computer Science::Computation and Language (Computational Linguistics and Natural Language and Speech Processing), Syllables, Magnetic Resonance Imaging, Sensory Systems, Auditory System, Coding mechanisms, Computer Science::Sound, Synopsis, Speech Perception, Female, Research Article, Neuroscience

Abstract

A neuroimaging study reveals how coupled brain oscillations at different frequencies align with quasi-rhythmic features of continuous speech such as prosody, syllables, and phonemes., Cortical oscillations are likely candidates for segmentation and coding of continuous speech. Here, we monitored continuous speech processing with magnetoencephalography (MEG) to unravel the principles of speech segmentation and coding. We demonstrate that speech entrains the phase of low-frequency (delta, theta) and the amplitude of high-frequency (gamma) oscillations in the auditory cortex. Phase entrainment is stronger in the right and amplitude entrainment is stronger in the left auditory cortex. Furthermore, edges in the speech envelope phase reset auditory cortex oscillations thereby enhancing their entrainment to speech. This mechanism adapts to the changing physical features of the speech envelope and enables efficient, stimulus-specific speech sampling. Finally, we show that within the auditory cortex, coupling between delta, theta, and gamma oscillations increases following speech edges. Importantly, all couplings (i.e., brain-speech and also within the cortex) attenuate for backward-presented speech, suggesting top-down control. We conclude that segmentation and coding of speech relies on a nested hierarchy of entrained cortical oscillations., Author Summary Continuous speech is organized into a nested hierarchy of quasi-rhythmic components (prosody, syllables, phonemes) with different time scales. Interestingly, neural activity in the human auditory cortex shows rhythmic modulations with frequencies that match these speech rhythms. Here, we use magnetoencephalography and information theory to study brain oscillations in participants as they process continuous speech. We show that auditory brain oscillations at different frequencies align with the rhythmic structure of speech. This alignment is more precise when participants listen to intelligible rather than unintelligible speech. The onset of speech resets brain oscillations and improves their alignment to speech rhythms; it also improves the alignment between the different frequencies of nested brain oscillations in the auditory cortex. Since these brain oscillations reflect rhythmic changes in neural excitability, they are strong candidates for mediating the segmentation of continuous speech at different time scales corresponding to key speech components such as syllables and phonemes.

Published

2013

18. Sensory Input Drives Multiple Intracellular Information Streams in Somatosensory Cortex.

Author

Alenda, Andrea, Molano-Mazón, Manuel, Panzeri, Stefano, and Maravall, Miguel

Subjects

SENSORY perception, NEURONS, BRAIN, SYNAPSES, LABORATORY rats

Abstract

Stable perception arises from the interaction between sensory inputs and internal activity fluctuations in cortex. Here we analyzed how different types of activity contribute to cortical sensory processing at the cellular scale. We performed whole-cell recordings in the barrel cortex of anesthetized rats while applying ongoing whisker stimulation and measured the information conveyed about the time-varying stimulus by different types of input (membrane potential) and output (spiking) signals. We found that substantial, comparable amounts of incoming information are carried by two types of membrane potential signal: slow, large (up-down state) fluctuations, and faster (>20 Hz), smaller-amplitude synaptic activity. Both types of activity fluctuation are therefore significantly driven by the stimulus on an ongoing basis. Each stream conveys essentially independent information. Output (spiking) information is contained in spike timing not just relative to the stimulus but also relative to membrane potential fluctuations. Information transfer is favored in up states relative to down states. Thus, slow, ongoing activity fluctuations and finer-scale synaptic activity generate multiple channels for incoming and outgoing information within barrel cortex neurons during ongoing stimulation. [ABSTRACT FROM AUTHOR]

Published

2010

19. Functional imaging and neural information coding

Author

Nevado, Angel, Young, Malcolm P., and Panzeri, Stefano

Subjects

*MAGNETIC resonance imaging, *BRAIN, *SENSORY neurons, *DIAGNOSTIC imaging

Abstract

Measuring functional magnetic resonance imaging (fMRI) responses to parametric stimulus variations in imaging experiments can elucidate how sensory information is represented in the brain. However, a potential limitation of this approach is that fMRI responses reflect only a regional average of neuronal activity. For this reason stimulus-induced changes in fMRI signal may not always reflect how sensory information is encoded by neuronal population activity. We investigate the potential problems induced by the finite spatial resolution of the fMRI signal by combining the principles of Information Theory with a computational model of neuronal activity based on known tuning properties of sensory cortex and assuming a linear spike rate to fMRI signal relationship. We found that the relationship between neuronal information and fMRI signal is highly nonlinear. It follows that the brain voxel experiencing the largest fMRI signal change is not necessarily the voxel encoding the most sensory information. Results also show that functional imaging data can be better interpreted in terms of neural information processing if the fMRI data and some knowledge about the tuning properties of the underlying neuronal populations are incorporated into a computational model. We discuss how imaging techniques themselves may provide an estimation of neuronal tuning properties. [Copyright &y& Elsevier]

Published

2004

20. Unique spatiotemporal fMRI dynamics in the awake mouse brain.

Author

Gutierrez-Barragan, Daniel, Singh, Neha Atulkumar, Alvino, Filomena Grazia, Coletta, Ludovico, Rocchi, Federico, De Guzman, Elizabeth, Galbusera, Alberto, Uboldi, Mauro, Panzeri, Stefano, and Gozzi, Alessandro

Subjects

*FUNCTIONAL magnetic resonance imaging, *PERSISTENT vegetative state, *MICE, *DIAGNOSTIC imaging, *NEURAL circuitry

Abstract

Human imaging studies have shown that spontaneous brain activity exhibits stereotypic spatiotemporal reorganization in awake, conscious conditions with respect to minimally conscious states. However, whether and how this phenomenon can be generalized to lower mammalian species remains unclear. Leveraging a robust protocol for resting-state fMRI (rsfMRI) mapping in non-anesthetized, head-fixed mice, we investigated functional network topography and dynamic structure of spontaneous brain activity in wakeful animals. We found that rsfMRI networks in the awake state, while anatomically comparable to those observed under anesthesia, are topologically configured to maximize interregional communication, departing from the underlying community structure of the mouse axonal connectome. We further report that rsfMRI activity in wakeful animals exhibits unique spatiotemporal dynamics characterized by a state-dependent, dominant occurrence of coactivation patterns encompassing a prominent participation of arousal-related forebrain nuclei and functional anti-coordination between visual-auditory and polymodal cortical areas. We finally show that rsfMRI dynamics in awake mice exhibits a stereotypical temporal structure, in which state-dominant coactivation patterns are configured as network attractors. These findings suggest that spontaneous brain activity in awake mice is critically shaped by state-specific involvement of basal forebrain arousal systems and document that its dynamic structure recapitulates distinctive, evolutionarily relevant principles that are predictive of conscious states in higher mammalian species. [Display omitted] • fMRI networks in awake mice depart from underlying anatomical structure • fMRI dynamics in wakeful mice is critically shaped by arousal-related nuclei • Occurrence and topography of rsfMRI coactivation patterns define conscious states • fMRI coactivation dynamics defines a signature of consciousness in the mouse brain Gutierrez-Barragan et al. show that spontaneous fMRI activity in the awake mouse brain exhibits unique spatiotemporal dynamics, recapitulating phylogenetically relevant signatures of consciousness in primates and humans. [ABSTRACT FROM AUTHOR]

Published

2022